An Empirical Investigation of Triple Helix and National ...
Transcript of An Empirical Investigation of Triple Helix and National ...
Asian Journal of Innovation and Policy (2017) 6.3:313-331
313
An Empirical Investigation of Triple Helix and National
Innovation System Dynamics in ASEAN-5 Economies
Munshi Naser Ibne Afzal*, Kasim Bin HJ. MD. Mansur
**,
Rini Suryati Sulong**
Abstract This paper exhibits the concept of Triple Helix model to explain and
link university-industry-government (Triple Helix) connections to national
innovation systems theory. The driver of this paper is to test the dynamics of Triple
Helix concept under national innovation system in the Association of South East
Asian Countries (ASEAN)-5 economies. Panel econometric analysis with cross-
sectional dependence (CD) test is applied to investigate the relationship amongst
Triple Helix variables. The empirical analysis employs innovation indicators of five
founding ASEAN countries namely Malaysia, Indonesia, Singapore, the Philippines
and Thailand for the period of 2000-2015 from an existing WDI and WCY database.
Econometric results support the two research questions of this study; firstly, there is a
significant relationship between innovation outcome and its key drivers under Triple
Helix context of National Innovation System in ASEAN-5 economies; secondly, the
extent of the relationship among government R&D expenditure with high-tech
productions are positive and significant while new ideas coming from universities as
scientific publications and high-tech production have positive relationship but not
significant yet in ASEAN-5 countries. Overall labor productivity is positive and
significant with innovation outcomes in ASEAN-5.
Keywords ASEAN-5, national innovation systems, Triple Helix model, university-
government-industry, Pooled OLS
I. Introduction
The main purpose of the study is to empirically investigate the concept of
Triple Helix (TH) model under national innovation system (NIS). This
research is an attempt to explain the relationship of Triple Helix actors and
measure empirically the extent of this relationship in the long run. Previous
Submitted, September 14,2017; 1st Revised, October 19, 2017; Accepted, December 15 *Corresponding, Business, Economics & Accountancy, University Malaysia Sabah,
Economics, Shahjalal University of Science & Technology and School of Commerce,
University of Southern Queensland, Australia; [email protected] ** University Malaysia Sabah; [email protected]; [email protected]
Asian Journal of Innovation and Policy (2017) 6.3:313-331
DOI: http//dx.doi.org/10.7545/ajip.2017.6.3.313
Asian Journal of Innovation and Policy (2017) 6.3:313-331
314
studies have postulated the concept more theoretically, while this study is the
first attempt to apply quantitative methodology to investigate this concept
empirically considering first five founder Association of South East Asian
Nations economies, namely Malaysia, Singapore, Indonesia, Thailand and the
Philippines as cross-sectional unit.
The research questions of this study are, firstly, how is Triple Helix model
characterized in general and in the context of ASEAN-5? To answer this
question, research followed the framework of Triple Helix model under the
National Innovation System based on the theory and descriptive analysis.
Secondly, how effective are the relationships among the actors of Triple Helix
model in this region? In order to find out the answer, this research applies
econometric techniques such as panel Regression with Driscoll-Kraay standard
errors.
Triple Helix theory is the sub-system yet very important component of
National Innovation system. Generally speaking, “the national innovation
system of a country is composed of different sub-systems ranging from
economic regime, financial structure and infrastructure to educational system,
cultural traditions, and so on. Thus, economic development is regarded as the
inter-action and co-evolutionary process of these sub-systems” (Freeman, 1987,
52-53; Nelson, 1993). Lundvall (1992, 22-24) defines “NIS as the elements
and relationships, which interact in the production, diffusion and use of new,
and economically useful knowledge and are either located within or rooted
inside the boarders of a nation state. In one a word the national innovation
system is defined as the network of agents and set of policies and institutions
that affect the introduction of technology that is new to the economy” (Sharif,
2006; Etzkowitz and Leydesdorff, 1997, 1998, 2000).
The synergy among universities, government and industry are also known as
the Triple Helix. The Triple Helix approach was introduced by Etzkowitz and
Leydesdorff (1997, 1998, 2000). This Triple Helix model focus on the
interaction among universities, industry and government and consider these
factors are the key to the improvement of conditions conducive to innovation.
Thus, all three have an important role to encourage the creation of advanced
economic climate.
Etzkowitz and Leydesdorff (2000) also argue that university, industry and
government are identified as the main pillars of many innovation systems
theories including NIS. In this paper, we introduce the Triple Helix systems as
a novel analytical concept that systematizes the key features of university-
industry-government interactions, so far loosely addressed as a ‘metaphor’ or a
‘framework’, into an ‘innovation system’ format that highlights the key new
sources of novelty and the dynamics of their interaction. Large developing countries (like Brazil, Russia, India, China, South Africa,
BRICS) postures the challenge for ASEAN to catch up with their growth
Asian Journal of Innovation and Policy (2017) 6.3:313-331
315
acceleration. Therefore, many economists (Stiglitz, Porter, Fagerberg,
Mazzucato, Lundvall, Nelson, Kim etc.) agree that only a “high-quality
innovation based growth, not just any growth could lead to a long-term
sustainable economic success”. Among the East Asian countries, Japan and
South Korea actively build up their science, technology and innovation (STI)
capacity with catch-up industrialization policies (Lundvall, 1992, 1993, 1998,
1999, 2003).
The ASEAN Economic Community (AEC) is heading towards technology
driven production advantages. The AEC is trying to establish an economic
region with a high level of competition, which requires a policy that includes
competition policy based on advance innovation system in macro level.
Based on the ASEAN Economic Blueprint, AEC becomes very necessary to
reduce the gap among ASEAN countries in terms of economic growth. Thus,
to address a sustainable economic growth, AEC can promote the concept of
Triple Helix model in this region. The relationship that appears in the Triple
Helix, generally stems from efforts to solve the problem and produce a strategy
when facing problems in innovation, not determined from a certain pattern.
Through this interaction process there will be changes in the actors and the
roles they are doing (Leydersdorff, 2000).
Cooperation among the government, businessman and intellectuals known as
the Triple Helix concept was necessary to build the foundation of a strong
national creative industry.
In order to formulate the policy that supports the aforementioned strategy,
the large ASEAN nations namely Malaysia, Indonesia, Thailand, Singapore
and the Philippines need to know where they stand and the gap that exist in
Triple Helix system to improve the innovation culture of the countries as well
the region as a whole.
Finally, it is argued that the Triple Helix interactions are an important factor
in driving competition and economic growth (Freeman, 1987; Lundvall, 1998).
This study will illustrate the concept by organizing this article into five major
sections. Firstly, section 1 Introduce the concept and illustrate the research
questions, section 2, Theoretical Background, section 3 will discuss ASEAN-5
cases, section 4 will describe data, variable and methodology and section 5 will
shed light on conclusion and policy implication to find out the answers of
research questions of this study.
Asian Journal of Innovation and Policy (2017) 6.3:313-331
316
II. Theoretical Background
1. Triple Helix Mechanism
In Triple Helix mechanism, innovation starts with an idea completely new or
from his or her experiences. This idea will make networks with other firms or
industries (creative industries those mostly involve in higher value-added
productions. This relationship is recognized as a Triple Helix of academic-
industry-government in innovation studies (Etzkowitz and Leydesdorff, 2000;
Patel and Pavitt, 1994).
This whole process can start with reverse system such as, an individual at a
firm might have a great idea of a technical process innovation (knowledge
stage) and refer back to university lab (Bianchini, Lissoni, Pezzoni and Zirullia,
2016). Only new idea alone cannot generate new innovation, there are other
socio-cultural factors induced the individual to do so. However, for the sake of
this study, we are not considering other factors like social or cultural rather we
are more focus on economic output contribution from high-technology
industry. According to new growth theory, innovation driven product has
increasing returns to scale as opposed to physical labor driven industries where
the law of diminishing returns tends to offset the constant increasing returns,
hence shows decreasing returns in neo classical production function.
Theoretically speaking, Romer’s new growth theory (1990) has been very
influential and inspired many econometric studies linking R&D, innovation
and hence in TH model.
Figure 1 Effective links and integration between the three spheres of Triple Helix (Saad and Zawdie, 2005)
Asian Journal of Innovation and Policy (2017) 6.3:313-331
317
III. Justification of Variable Selection and Descriptive Study
1. Variable Selection
Following the theory of Schumpeter and New Growth Theory, this paper
uses innovation as a concept of new process, new method, new market, new
source of supply, new industry hence, new commercially value-added products
for the economy (Schumpeter, 1942). Roger 2003 illustrates, this innovation
diffuses from micro agent at individual or organizational level to macro stage
such as National Innovation System of a country or region.
Therefore, to capture the whole process from micro to macro level, this
study uses four different variables.
Generally speaking, in the case of finding the relationship between how idea
generation linked with industry outcome, “the input-output indicators of NIS
are mainly patents granted, scientific publications, and output of high-tech
industries can be considered” (Hatzichronoglou, 1997; Afzal, 2014, 507-515;
Afzal, 2013). We can explain all four proxy variables one by one to justify the
variable selection process of this research. Firstly, the number of employees of
a firm can be considered as a proxy of its size and industrial organization (Blau
and Schoenherr, 1971) which this research use labor productivity as proxy for
analysis.
R&D expenditure as percentage of GDP uses to measure the intensity of
innovation-embodied production of intermediate and capital goods. This could
also explain the TH model as technology commercialization such as High-
Tech products (Hatzichronoglou, 1997). Whereas patents or high-tech products
can be used as output indicators for R&D based science and technology
research (Leydesdorff and Smith, 2014).
Pires and Garcia (2012) argue that total factor productivity (TFP) is
responsible for technical efficiency, innovation and growth differences
between countries. Recent econometric studies (Faustino and Matos, 2015; Lee
and Narjako, 2015; Felsenstein, 2015) also confirm that higher TFP focusing
on human capital development or increase labor productivity may lead to
process innovation in an economy (Felsenstein, 2015).
Scientific and technical publications are another recent and popular proxy
measure of new idea generation in universities or research institutes.
Castellacci and Natera (2013) define it as the result of research and
development funding from government activities by public system. Cai (2011),
Pan Hung and Lu (2010) and Chang (2015) consider that scientific
publications may be a very important proxy to measure in macro level study to
identify whether these ideas are actually generating or linking the creative
industries in individual countries or region backed by public research spending.
Asian Journal of Innovation and Policy (2017) 6.3:313-331
318
High-tech or creative industries generally refer to the scope of the industry is
automotive industry, the drug industry, software industry, bio-technology and
other industrial forms such as creative industries. The creative industries can
be defined as a collection of economic activities associated with the creation or
use of knowledge and information. “High-tech exports are one of the most
popular proxies for innovation and NIS efficiency output (Afzal, 2013; Cai,
2011). Afzal and Lawrey (2012, 54) consider high-tech exports as
commercialization of valuable knowledge creation”. Fan (2011) argues that
high-tech exports and patents outcome can represent the overall national
innovation capacity and economic development as a whole. Therefore, for the
purpose of this paper, we use high-tech exports as percentage of total
manufacturing to capture the innovation outcome process in ASEAN.
2. Data Set and Descriptive Analysis
The data set consists of ASEAN-5 cross-country observations over the 2000-
2015 period obtained from the data base of World Development Indicators1,
International Telecommunication Union (ITU) and World Competitiveness
Year Book (WCY). The variables are HTE which measures the high-tech
export as percentage on total manufacturing as proxy of innovation outcome,
RDE as a proxy of research and development expenditure funded by
government mostly, SJA as proxy of number of Scientific publication per 1000
population for new idea generation or knowledge spill over from universities,
LPP is the proxy of labor productivity overall in tertiary education. Descriptive
analysis of the dataset is given below.
The visualization above shows the scientific and technical journal articles
published by the ASEAN countries for the period 2000 to 2015. Every country
is producing scientific and technical journal articles and the number is
increasing from the beginning of study period of analysis except the case in
Indonesia. From 2013 to 2015, scientific and technical journal articles
publication in Indonesia is constant. The lowest publication per 1000
populations is found in the Philippines from 2000 to 2008 whereas Thailand’s
publication number is increasing, but without any significant leap visible.
Whilst, Singapore had a small lift in scientific and technical journal article
publications in year 2003, which sustained till 2004 and then followed by a
steady increasing rate. The amount of Malaysia’s scientific and technical
journal articles faced a fall in year 2001. According to the Figure 2, Malaysia
has the highest number of publications than the other countries studied during
1 http://data.worldbank.org/indicator
Asian Journal of Innovation and Policy (2017) 6.3:313-331
319
2009 to 2015. In 2015, Malaysia published about 20,000 scientific and
technical journal articles.
Figure 2 Scientific and technical journal articles
Source: Author calculation
Figure 3 Patent applications, residents
Source: Author calculation
0
5000
10000
15000
20000
25000
2000
2001
2002
2003
2004
2005
2006
2007
2008
2009
2010
2011
2012
2013
2014
2015
Indonesia Malaysia Philippines
Singapore Thailand
0
200
400
600
800
1000
1200
1400
1600
1800
2 0 0 0 2 0 0 1 2 0 0 2 2 0 0 3 2 0 0 4 2 0 0 5 2 0 0 6 2 0 0 7 2 0 0 8 2 0 0 9 2 0 1 0 2 0 1 1 2 0 1 2 2 0 1 3 2 0 1 4 2 0 1 5
Indonesia Malaysia Philippines Singapore Thailand
Asian Journal of Innovation and Policy (2017) 6.3:313-331
320
The state of patent applications claim by the residents of the five ASEAN
countries is shown in Figure 3. Among the countries, the Philippines holds the
least number of patent claim between the study period 2000 to 2015. Indonesia
improves in patent claim in 2008, and the upward trend is sustained more in
2014, which continued till 2015. Singapore had the highest patent application
claims in 2015 among the study countries. Claiming 1300 applications,
Malaysian patent claim peaked highest in 2014 even though it remained
constant in 2004 to 2006 and 2009 to 2010. On the other hand, the country also
faces a slump in the number of patent application in 2011 and in 2015.
Figure 4 High-technology exports (% of manufactured exports)
Source: Author calculation
Generally speaking, high-technology exports are products with high R&D
intensity, such as in aerospace, computers, pharmaceuticals, scientific
instruments, and electrical machinery. The Figure 4 illustrates the high-tech
export as a total percentage of manufactured exports for the five ASEAN
countries. Here, high-tech exports were higher in the period 2000 and
gradually decreased in 2015 for every country. The Philippines ranked top
between 2000 to 2015 whereas, Malaysia and Singapore show a consistent low
performance in high-tech export over the years. In 2015, Malaysia had around
43% share of high-tech exports of total exports whereas the high-tech export of
Singapore was around 50% of its total export at that period. Thailand’s share
of high-tech export was around 34% in 2000 and declined to approximate 22%
in 2015. The smallest share can be seen with Indonesia having 16% in 2000-
reduced to around 7% in 2015. The slump of the high-tech exports of all
0
20
40
60
80
2 0 0 0 2 0 0 1 2 0 0 2 2 0 0 3 2 0 0 4 2 0 0 5 2 0 0 6 2 0 0 7 2 0 0 8 2 0 0 9 2 0 1 0 2 0 1 1 2 0 1 2 2 0 1 3 2 0 1 4 2 0 1 5
Indonesia Malaysia Philippines
Singapore Thailand
Asian Journal of Innovation and Policy (2017) 6.3:313-331
321
countries from period 2006 to 2011 can be denoted as one of the key events in
the ASEAN economy.
The share of high-tech exports in developed economies improved basically
due to the availability of cheaper raw materials, cheaper labor; increased
efficiency and stronger entitlement of investment in required R&D sector;
broadened outlook on high-tech trade; enhancing the quality of education; etc.
Figure 5 Labor productivity
Source: Author Calculation
The labor productivity of five ASEAN countries of period 2000 to 2015 is
shown in the Figure 5 above. As we see here, Singapore holds the highest
labor productivitywith 30% in 2000 and increase up to 45% in 2015. Malaysia
follows Singapore having 10% productivity growth in 2000 and stayed around
19% in 2015.
Thailand lies above Indonesia and Philippines in labor productivity index
from 2000 to 2015. Thailand’s ratings have increased to nearly about 1.5%
since 2000 to 2015. On the other hand, Indonesia and Philippines could not go
above 5%.
This situation implies that Singapore has a higher living standard than the
other countries. Higher labor productivity triggers the overall economic
development of a nation by improving efficiency in physical capital, method of
technology and human capital etc.
-
10.00
20.00
30.00
40.00
50.00
2000
2001
2002
2003
2004
2005
2006
2007
2008
2009
2010
2011
2012
2013
2014
2015
Indonesia Malaysia Philippines
Singapore Thailand
Asian Journal of Innovation and Policy (2017) 6.3:313-331
322
Figure 6 Total expenditure on R&D ($) Source: Author calculation
The expenditure on R&D can directly affect the innovation condition of a
country. By the above illustration a greater investment in R&D is seen in the
case of Singapore and Thailand. In addition, Thailand ranked as the highest
investor in R&D among the five ASEAN countries for the period 2000 to 2015.
Where Singapore stands second. The R&D expenditure is least in Indonesia.
Malaysia and Philippines follow an identical trend in R&D expenditure. These
countries raised their R&D expenditure in 2007 which is found to be constant
until 2015. The same augmentation in R&D expenditure is found in case of
Singapore and Thailand in 2005 and being constant from 2012 to 2015 in
Figure 6.
IV. Econometric Methodology
Our main objectives of the research are to find out Triple Helix relationship
under NIS and how effective this relationship in long run. Therefore, our
panel econometric model can be given as follows in order to test long run
associations of our variables to justify the research objectives:
HTEit = α+α1 SJAit+ α2RDEit+ α3LPPit+ µ it………………………………….(1)
-
2000.00
4000.00
6000.00
8000.00
10000.00
2000
2001
2002
2003
2004
2005
2006
2007
2008
2009
2010
2011
2012
2013
2014
2015
Indonesia Malaysia Philippines
Singapore Thailand
Asian Journal of Innovation and Policy (2017) 6.3:313-331
323
Where the subscript i=1… N denotes the country (in our study, we have 5
ASEAN countries) and t= 1…T denotes the time period (our time frame is
2000-2015), HTE is the high-tech export as percentage on total manufacturing,
RDE is research and development expenditure (as % of GDP), SJA as proxy of
number of Scientific publication per 1000 population, LPP is the overall labor
productivity and µ is the error term in equation 1.
1. Cross Sectional Dependence Test
It is commonly assumed that distribution in panel data models is cross-
sectional independent, especially when the cross-section dimension (N) is large.
There is, however there is sometimes we have found the evidence of Cross-
section Dependence (CD) in panel data set. In order to test whether or not the
residuals from a panel estimation of the regression model are spatially
independent, authors perform Pesaran’s (2004) CD test. The null hypothesis of
the CD test states that the residuals are cross-section ally uncorrelated.
Correspondingly, the test’s alternative hypothesis presumes that spatial
dependence is present (Afzal and Gow, 2016) (Kao and Chiang, 2000)
(Asteriou and Hall, 2007) (Bai and Ng, 2004; Peterson, 2007; Driscoll and
Kraay, 1998).
In this study, Pesaran’s test of cross sectional independence = 2.077, Pr =
0.0378, average absolute value of the off-diagonal elements = 0.160. On
average, the (absolute) correlation between the residuals of two stocks is 0.354.
Therefore, it comes as no surprise that Pesaran’s CD test rejects the null
hypothesis of spatial independence on any standard level of significance. As a
result, our panel model should be estimated with Driscoll-Kraay standard
errors since they are robust to very general forms of cross-sectional and
temporal dependence (Driscoll and Kraay, 1998).
Pesaran's test of cross sectional independence = 2.077, Pr = 0.0378
Average absolute value of the off-diagonal elements = 0.354
Therefore, this research follows regression model by Pooled OLS with
Driscoll and Kraay standard errors. Somewhat arbitrarily, a lag length of 8 is
chosen. However, the results turn out to be quite robust to changes in the
selected lag length.
2. Panel Unit Root Test
Cointegration test usually applies to understand the long run relationship
between all the variables. However, before doing this test, researcher needs to
Asian Journal of Innovation and Policy (2017) 6.3:313-331
324
find out the stationary test of variables using unit root analysis at level (Dickey
and Fuller, 1981; Phillips and Perron, 1988). However, in presence of cross
sectional dependence, we cannot apply conventional unit root test. In this case,
this study applied Westerlund (2007) second generation unit root test in the
presence of cross section dependence (IPS, 2003; Levin et al., 2002).
3. Empirical Results
3.1 Results of Panel Unit Root Tests
To investigate the stationarity of the series used, we applied the unit root
tests on panel data in the presence of cross sectional dependence. The results of
these tests are presented in the following table:
Table 1 Results for panel unit root tests in the presence of CD
Variables
Test
Level First Difference
t-statistics p-value t-statistics p-value
HTE -2.20 0.153 -1.77 0.446
RDE -3.08 0.002 -2.92 0.006
SJA -1.91 0.343 -2.69 0.021
LPP -3.01 0.003 -1.63 0.531
Source: Author calculation
In this table 1, all the variables are not non-stationary at the level or first
difference. In order to run cointegration test, there must have two conditions
(Phillips and Moon, 1999; Stock and Watson, 1993; Saikkonen, 1991; Mark
and Sul, 2003).
Variables at level (1) are non-stationary or have a unit root.
But at the 1st difference, they become stationary.
This study cannot find the presence of above conditions. Therefore, we
cannot apply the conventional co-integration test in the presence of CD.
According to Pedroni's Residual-Based Panel Cointegration Tests (1999, 2004;
Kao, 1999; Kök et al., 2010; Granger, 1969; Engle and Granger, 1987;
Johansen, 1991; Philips and Ouliaris, 1990; Lee, 2005; Adhikari & Chen, 2012;
Jebli & Youssef, 2015) have mentioned cases like this, the research should
apply Error Correction Model (ECM) like Driscoll-Kraay standard errors estimations in pooled OLS model.
Asian Journal of Innovation and Policy (2017) 6.3:313-331
325
3.2 The Regression with Driscoll-Kraay Standard Errors Driscoll and Kraay (1998) standard errors for coefficients estimated by
pooled OLS/WLS or fixed-effects (within) regression. The error structure is
assumed to be heteroskedastic, auto correlated up to some lag and possibly
correlated between the groups (panels). These standard errors are robust to
general forms of cross-sectional (spatial) and temporal dependence. Because
this nonparametric technique of estimating standard errors places no
restrictions on the limiting behavior of the number of panels, the size of the
cross-sectional dimension in finite samples does not constitute a constraint on
feasibility.
Usually, DOLS, PMG, and FEM estimator assume that all cross-section
units are independent. However, if the cross-section units show dependence
among them, that could lead to the consequence of unobserved heterogeneity
due to omitted observed common factors, spatial spillover effects, unobserved
common factors, or general residual interdependence (Pesaran, 2004). In cases,
standard techniques that do not take account of this dependence would yield
inconsistent estimates of the parameter standard errors, producing incorrect
inference and test statistics. Consequently, in order to correct for the presence
of cross-sectional dependence, we employ DK estimator.
The Regression with Driscoll-Kraay standard errors estimations and the
results are presented in Table 2.
Table 2 Results for Pooled OLS in presence of cross-section dependence
Source: Author calculation
Results for Pooled OLS using Driscoll-Kraay (DK) standard errors
estimations from table 02 show that, the elasticity of SJA across the panels was
calculated as 0.0081. This means that a 1% increase in Scientific publications
in universities or research centers in the ASEAN-5 countries generates
approximately 0.0081% increase of value added high-technology production in
the long-run. The variable is not significant at 5% and 10% level, which
Dependent Variable: HTE Method: Driscoll-Kraay standard errors estimations in Pooled OLS
Variable Coefficient Std. Error t-Statistic Prob.
SJA 0.0081 0.004796 1.76369 0.153
RDE 0.012 0.00363 -5.017581 0.029
LPP 1.78 0.367460 0.394512 0.008
C 33.2066 4.7298 7.01267 0.002
R-squared 0.2043 Root MSE 18.19
Adjusted R-squared 0.345 Prob > F 0.000
Asian Journal of Innovation and Policy (2017) 6.3:313-331
326
implies that there is no significant impact on high-tech goods production from
university or research centers publication outcomes in ASEAN. This also tells
the story that the link between university and industry collaboration is not so
much solid. This is an interesting finding from our research. Elastic
coefficients of R&D are calculated as 0.012%. Therefore, an increase of 1% in
R&D constitutes a positive effect on high-tech production at the rate of
approximately 0.012%. On the other hand, a 1% increase in labor productivity
(LPP) causes 1.78 % increases of high-tech productions in the long-run.
According to the test results of the DK estimation, RDE and LPP in the long-
run affect high-tech goods production significantly both in a positive and
statistical way as expected. Furthermore, the findings indicate a positive
relationship between Scientific publications mostly from the universities (SJA)
and high-tech goods production (THE), but statically non- significant. ASEAN
member states can take this important finding into consideration to formulate
their TH policy implications for future.
The above sections analyze the feedback effect between high-tech based
productions, scientific publications per 1000 populations in ASEAN, R&D and
labor productivity. Our model organizes and estimates such effects, and the
analysis shows that research expenditure from government, overall labor
productivity and Scientific publications share a positive relationship with
High-technology based production, although industry represented by (high-
tech production)-university (idea generation through scientific publications)
linkage is still weak in ASEAN region under the broad umbrella of National
Innovation system.
V. Contribution of This Study
This paper contributes to the literature in four ways. Firstly, to the best of our
knowledge, little is known about TH and NIS relationship in ASEAN countries
until now. Secondly, this paper presents what, we believed, is the first panel
data study of the concept of NIS and TH relationship and the first from the
perspective of the ASEAN countries.
Thirdly, due to the limitation of homogenous panel data approaches such as
the DOLS, PMG technique, this study has applied the DK model by Driscoll
and Kraay (1998) where these standard errors are robust to general forms of
cross-sectional (spatial) and temporal dependence when the time dimension
becomes large. Cross sectional dependence (CD) test has been done by
Pesaran’s test of cross sectional independence (Peterson, 2007). Fourthly, this study examines the relationship of idea generation to the
commercialization of knowledge using the proxy variables of scientific and
Asian Journal of Innovation and Policy (2017) 6.3:313-331
327
technical journal articles, High-tech exports as a percentage of total
manufacturing exports. The results show a positive, but the weak relationship
in ASEAN-5 countries. This is an interesting outcome where recently the
ASEAN region is considered by many researchers as the region that region
possesses “World’s Most Influential Scientific Minds” (Chuah et al., 2016).
One limitation of this study may be that the data sample is small due to
missing data that required the application of more econometric methods to test
the hypothesis. Usually, variables like tertiary education expenditure, skills of
the labor force, schooling in tertiary level are important to test our objective of
the study. The unavailability of data for all the ASEAN-5 member countries
does not allow us to incorporate these variables in our analysis. In future, the
first difference GMM method with short time span, and the panel dynamic
ordinary least square technique (DOLS) for testing the VECM model to check
the serial correlation problem and the variance decomposition model to
investigate the pass-through of external shocks to each variable in the model
could be deployed. Finally, our results and discussion show that the most
important contribution to high-tech productions as a proxy of innovation
output has been made by RD expenditure and labor productivity. The scientific
publications and high-tech productions have weak linkage meaning that the
Triple Helix model under NIS is not working at its optimum in ASEAN-5
countries. This is in line with the research of Hassan and Bakri (2016), Chuah
et al. (2016), Din, Anuar and Usman (2016), and Yaacob, Shaupi and Shuaib
(2016). It is very important to engage in strong and robust collaboration among
government-industry and university relationship for the long run sustainable
economic growth of this region.
VI. Conclusion and Policy Discussions
Nowadays, to achieve a competitive economy, the focus should be oriented
on national innovation system with some key factors, such as high-technology
based value added products, R&D, new idea generation through scientific
publications and overall labor productivity.
In this context, technology based production from high-tech industry backed
by government and universities (following the theory of Triple Helix model)
can be a powerful way to develop knowledge economy, which in turn can
increase competitive performance and long-term economic development in the
ASEAN region.
The aim of this study was to investigate the link between innovation output (measured by high-tech goods production), government support for innovation
(measured by R&D expenditure), and new idea generation from higher
Asian Journal of Innovation and Policy (2017) 6.3:313-331
328
education institutes (measured by scientific and technical article publications)
under National Innovation and Triple Helix context in ASEAN-5 countries
over the period 2000-2015.
Our results provide evidence that economically value-added technology
based production depends on new ideas from universities, government R&D
expenditure and overall labor productivity in big ASEAN economies.
Although the link between idea coming from high education institutes and
transferred to high-tech industries are not yet strongly shape up in ASEAN-5.
This is a major empirical finding from our research.
The empirical results support the two research questions of this study, Firstly,
there is long run relationship between innovation outcome and its key drivers
under triple helix context of national innovation system in ASEAN-5
economies; Secondly, the extent of relationship among government R&D
expenditure with High-tech productions are positive and significant while new
ideas coming from universities as scientific publications and high-tech
production have positive relationship but not significant yet in ASEAN-5
countries. Overall labor productivity is positive and significant with innovation
outcomes in the region.
In short, a 1% increase in SJA, RDE and LPP affects high-tech production
by 0.0035%, 0.0762% and 3.2% successively in the long run.
The main findings show that the most important contribution to high-tech
productions as a proxy of innovation output has been made by RD expenditure
and labor productivity. The scientific publications and high-tech productions
have weak linkage meaning that the Triple Helix model under NIS is not
working at its optimum in ASEAN-5 countries. It is very important to make
strong and robust collaboration among government-industry and university
relationship for the long run sustainable economic growth of this region. This
finding, suggest that, universities besides being promoted quality and
excellence of students, they should lead them to engage in research and patent
activity with local industry in order to enhance the performance in National
Innovation System.
Lack of social and cultural factors such as, innovation culture within the
industry, university and government policy, social motivational factors for
innovation, institutional regimes, regulatory factors, political stability and
foreign policy were not considered in this research. This is perhaps the main
limitation of this study. To overcome this limitation, the future researcher can
pursue a primary survey method at a micro level to identify the aforementioned
factors to better understand the dynamics Triple Helix system and develop
overall innovation policy of the nation as well as the region.
Asian Journal of Innovation and Policy (2017) 6.3:313-331
329
References
Adhikari, D. and Chen, Y. (2012) Energy consumption and economic growth: A panel
cointegration analysis for developing countries, Review of Economics & Finance,
3(2), 68-80.
Afzal, M.N.I. and Gow, J. (2016) Electricity consumption and information and
communication technology in the next eleven emerging economies, International
Journal of Energy Economics and Policy, 6(3), 1-8.
Afzal, M.N.I. (2014) An empirical investigation of the national innovation system
(NIS) using data envelopment analysis (DEA) and the TOBIT model, International
Review of Applied Economics, 28(4), 507-523.
Afzal, M.N.I. (2013) Are science valleys and clusters panacea for a knowledge
economy? An investigation on regional innovation system (RIS) - concepts, theory
and empirical analysis, Asian Research Policy, 4(2), 114-125.
Afzal, M.N.I. and Lawrey, R. (2012) A measurement framework for knowledge-
based economy (KBE) efficiency in ASEAN: a data envelopment (DEA) window
approach, International Journal of Business and Management, 7(18), 57-68.
Asteriou, D. and Hall, S.G. (2007) Applied econometrics: A Modern Approach Using
EViews and Microfit (Revised ed.), New York: Palgrave Macmillan.
Bai, J. and Ng, S. (2004) A panic attack on unit roots and cointegration,
Econometrica, 72(4), 191-221.
Bianchini, S., Lissoni, F., Pezzoni, M. and Zirullia, L. (2016) The economics of
research, consulting, and teaching quality: theory and evidence from a technical
university, Economics of Innovation and New Technology 25(7), 668-691.
Blau, P.M. and Schoenherr, R. (1971) The structure of organizations, New York, NY:
Basic Books.
Cai, Y. (2011) Factors affecting the efficiency of the BRICSs’ national innovation
systems: A comparative study based on DEA and Panel Data analysis. discussion
paper, No. 2011-52.
http://www.economics-ejournal.org/economics/discussionpapers/2011-52.
Cetin, M., Gunaydın, D., Cavlak, H. and Topcu, B. (2014) Unemployment and its
impact on economic growth in the European Union: An evidence from panel data
analysis, Regional Economic Integration and the Global Financial System, 12(1),
1-11.
Chuah, F., Ting, H., Run, E.C., and Cheah, J.H. (2016) Reconsidering what
entrepreneurial intention implies: The evidence from Malaysian University
students, International Journal of Business and Social Science, 7(9), 85-98.
Dickey, D. and W. Fuller, W. (1981) Likelihood ratio statistics for autoregressive time
series with a unit root, Econometrica, 49(1), 1057-1072.
Din, B.H., Anuar, A.R. and Usman, M. (2016) The effectiveness of the
entrepreneurship education program in upgrading entrepreneurial skills among
public university students, Procedia-Social and Behavioral Sciences, 224(1), 117-
123.
Asian Journal of Innovation and Policy (2017) 6.3:313-331
330
Driscoll, J.C. and A.C. Kraay. (1998) Consistent covariance matrix estimation with
spatially dependent panel data, Review of Economics and Statistics 80(1), 549-560.
Engle, R.F. and Granger, C.W.J. (1987) Cointegration and error correction:
Representation, estimation and testing, Econometrica, 55(1), 251-276.
Granger, C.W.J. (1969) Investigating causal relations by econometric models and
cross-spectral methods, Econometrica, 35(1), 424-438.
Hassan, R.A. and Bakri, M.Z. (2016) Self-efficacy and self-independence in
promoting self-employment intention among university students, Journal of
Research in Business, Economics and Management, 6(2), 888-893.
Im, K.S., Pesaran, M.H. and Shin, Y. (2003) Testing for unit roots in heterogeneous
panels, Journal of Econometrics, 115(1), 53-74.
Jebli, M.B. and Youssef, S.B. (2015) Output, renewable and non-renewable energy
consumption and international trade: Evidence from a panel of 69 countries,
Renewable Energy, 83(1), 799-808.
Johansen, S. (1991) Estimation and hypothesis testing of cointegrating vectors in
Gaussian vector autoregression models, Econometrica, 59(1), 1551-1580.
Kao, C. (1999) Spurious regression and residual-based tests for cointegration in panel
data, Journal of Econometrics, 90(1), 1-44.
Kao, C. and Chiang, M.H. (2000) On the estimation and inference of a cointegrated
regression in panel data, Advances in Econometrics, 15(1), 179-222.
Kök, R., Ispir, M.S. and Arı, A. (2010) Rich requirements of the country and the least
developed countries fund transfer mechanism: An essay on universal distribution
parameter, 2nd International Conference on Economics, Turkey Economic
Association, Cyprus.
Lee, C.C. (2005) Energy consumption and GDP in developing countries: A
cointegrated panel analysis, Energy Economics, 27 (3), 415-427.
Leydesdorff, L. and Smith, L.H. (2014) The Triple Helix in the context of global
change: dynamics and challenges, Prometheus 32(4), 321-336.
Lundvall, B. (1992) National Systems of Innovation: Towards a Theory of
Innovation and Interactive Learning, London: Pinter.
Lundvall, B. (1993) User-producer relationships, national systems of innovation and
internationalization, In: Technology and the Wealth of Nations, Foray, D and
Freeman, C (eds), London: Pinter.
Lundvall, B. (1998) Why study national systems and national styles of innovation?
Technology Analysis and Strategic Management, 10(4), 407-422.
Lundvall, B. (1999) National business systems and national systems of innovation,
special issue on business systems, International Studies of Management and
Organization, 29(2), 60-77.
Lundvall, B. (2003) National Innovation System: History and Theory, Aalborg
University, Aalborg, Denmark.
Mark, N.C. and Sul, D. (2003) Cointegration vector estimation by panel DOLS and
long-run money demand, Oxford Bulletin of Economics and Statistics, 65(5), 655-
680.
Patel, P and Pavitt, K. (1994) National innovation systems: why they are important,
and how they might be measured and compared, Economics of Innovation and
New Technology, 3(1), 77-95.
Asian Journal of Innovation and Policy (2017) 6.3:313-331
331
Pedroni, P. (1999) Critical values for cointegration tests in heterogeneous panels with
multiple regressors, Oxford Bulletin of Economics and Statistics, 61(1), 653-670.
Pedroni, P. (2000) Fully modifed OLS for heterogeneous cointegrated panel,
Advances in Econometrics, 15(1), 93-130.
Pedroni, P. (2004) Panel cointegration: asymptotic and finite sample properties of
pooled time series tests with an application to the PPP hypothesis, Econometric
Theory, 20(1), 597-625.
Pesaran, M. (2004) General diagnostic tests for cross section dependence in panels,
Cambridge Working Papers in Economics, No. 0435, Faculty of Economics,
University of Cambridge.
Petersen, M.A. (2007) Estimating standard errors in finance panel data sets:
comparing approaches, Working Paper, Kellogg School of Management,
Northwestern University.
Phillips, P.C. and Ouliaris, S. (1990) Asymptotic properties of residual based test for
cointegration. Econometrica, 58(1), 165-193.
Phillips, P.C.B. and Moon, H.R. (1999) Linear regression limit theory for
nonstationary panel data, Econometrica, 67(1), 1057-1111.
Saikkonen, P. (1991) Asymptotically efficient estimation of cointegration regressions,
Econometric Theory, 7(1), 1-21.
Schumpeter, J.R. (1942) Capitalism, Socialism and Democracy, New York: Harper &
Row.
Stock, J.H. and Watson, M.W. (1993) A simple estimator of cointegrating vectors in
higher order integrated systems, Econometrica, 61(1), 783-820.
Westerlund, J. (2007) Testing for error correction in panel data, Oxford Bulletin of
Economics and Statistics, 69(6), 709-748.
World Competitiveness Yearbook (WCY CD-ROM) (2000-2015), Switzerland: IMD.
World Development Indicators (WDI online) (2000-2015), Washington: World Bank.
Yaacob, M.R., Shaupi, N.S.A. and Shuaib, A.S.M. (2016) Perception towards factors
that affect the effectiveness of an entrepreneurship training program, Journal of
Entrepreneurship and Business, 4(1), 50-58.